Breakup behavior of a molten metal jet

• Published in: The International journal of heat and fluid flow Vol. 50; pp. 27 - 37
• Main Authors: Oh, Yong Suk, Choi, Dong Yun, Son, Jae Yeol, Kim, Bo Young, Kang, Hyun Wook, Chang, Cheong Bong, Moon, Jeong-Tak, Sung, Hyung Jin
• Format: Journal Article
• Language: English
• Published: New York, NY Elsevier Inc 01.12.2014; Elsevier
• Subjects: Amplitude modulation; Breakup; Breakup length; Coalescence; Droplets; Dynamic contact angle; Exact sciences and technology; Fluid dynamics; Fluid flow; Fundamental areas of phenomenology (including applications); Hydrodynamic stability; Jets; Liquid metals; Mathematical models; Molten metal jet; Perturbation methods; Physics; Surface instability; Surface-tension-driven instability; Turbulent flows, convection, and heat transfer; Waveforms; Amplitude modulation; Dynamic contact angle; Molten metal jet; Breakup length; Surface instability; Ruptures; Digital simulation; Liquid metals; Contact angle; Periodic perturbation; Hydrodynamic instability; Jets; Modelling; Surface tension; Melts
• ISSN: 0142-727X; 1879-2278
• DOI: 10.1016/j.ijheatfluidflow.2014.05.002

•Breakup behavior of a molten metal jet into a still gas is numerically studied.•Droplet formation by imposing a sinusoidal waveform perturbation.•Effect of the modulated amplitude on the coalescence and separation.•Effects of the oscillation amplitude, the Strouhal number and the Weber number.•Optimal conditions for the continuous generation of uniform droplets. The breakup behavior of a molten metal jet into a still gas was studied numerically. Droplet formation was modeled by imposing a sinusoidal waveform perturbation or an amplitude-modulated waveform perturbation. The effect of the temperature on the jet breakup behavior was examined by modeling the liquid metal properties, including density, viscosity, and surface tension, as a function of the temperature. The process by which a molten metal jet was ejected from an orifice exit was modeled to include the wetting of the molten metal on the orifice surface at the gas interface using a dynamic contact angle (θD). The effects of the oscillation amplitude (A=0.10–0.30), the Strouhal number (St=0.20–0.50) and the Weber number (We=11.63–129.19) were studied. The imposition of a periodic perturbation yielded linear or nonlinear breakup behavior in the molten metal jet. The conditions found to be optimal for the continuous generation of uniform droplets were identified by optimizing the uniformity of the main droplet, the regular distance between main droplets, the presence of satellite droplets, and the coalescence of the droplets due to surface instabilities and hydrodynamic interactions. The effects of the modulated amplitude (B) and the frequency ratio (N) on the coalescence and separation of neighboring droplets were examined.